KR102516301B1 - Magnetic materials identifying apparatus and banknote sorter hving said apparatus - Google Patents

Abstract

The present invention discloses a magnetic material identification device and a banknote counter having the same. The magnetic material identification device includes: a magnetic sensing unit that magnetizes a plurality of magnetic materials having different characteristics present in a bill to be transported and distinguishes and detects the plurality of magnetic materials; a magnetization unit capable of magnetizing the plurality of magnetic materials present in the banknote; and a magnetization current supply unit supplying a current for forming a magnetic field for magnetizing the plurality of magnetic materials in the magnetic sensing unit, wherein the magnetization current supply unit has a magnetic field in a direction opposite to that of the magnetic field formed in the magnetization unit. Characterized in that a direct current is applied to form.

Description

Magnetic material identification device and bill counter {MAGNETIC MATERIALS IDENTIFYING APPARATUS AND BANKNOTE SORTER HVING SAID APPARATUS}

The present invention relates to a magnetic material identification device and a banknote counter having the same, and more particularly, for banknotes containing a plurality of magnetic materials having different characteristics, a plurality of magnetic materials can be distinguished and identified according to coercive force. It relates to a magnetic material identification device capable of more precisely determining the authenticity of banknotes and a banknote counter having the same.

In general, a banknote counter is a device used to automatically count and classify banknotes using a mechanical/electronic device, and is also used to count and classify not only banknotes but also securities such as checks and gift certificates as well as various types of paper. . At this time, the term 'banknote' is meant to include not only banknotes but also securities such as checks, bills, and gift certificates.

In general, a bill counter includes a supply roller for supplying bills therein to count bills, a paper feed roller for transporting the supplied bills, a take-out roller for taking out bills supplied by the supply roller and the paper feed roller, and supplying bills. A driving motor for driving a roller, a paper feed roller, and a take-out roller, and a counting unit for counting bills conveyed through the rollers are included.

On the other hand, with the development of counterfeit money technology, a function for detecting counterfeit money is required for banknote counters, and various counterfeit detection functions are installed. The bill counter basically includes a counter sensor. The counter sensor is composed of light emitting and receiving infrared sensors, and counts the number of transferred bills using infrared rays and measures the thickness of the bills. In addition, most banknote counters are equipped with ultraviolet (UV: Ultra Violet) sensors to detect counterfeit bills. The banknote counter detects counterfeit bills by irradiating ultraviolet rays on one side of the bill being transported using an ultraviolet sensor. For reference, bills are usually made of cotton paper, which is different from other counterfeit bill materials in terms of UV absorption. Accordingly, the bill counter can detect whether the bill is counterfeit through the ultraviolet sensor.

In addition, bill counters use a magnetic sensor (magnetic sensor) to detect magnetic ink (e.g., iron oxide, etc.) Counterfeiting is determined by detecting the presence or absence of magnetic ink in the area where magnetic ink should exist.

These conventional banknote counters discriminate counterfeit money by detecting only the presence or absence of magnetic ink contained in the banknote, even though it is impossible to detect it with the naked eye or optical counterfeit detection methods. It is difficult to distinguish, so it is difficult to accurately detect whether it is pneumococcal or counterfeit.

On the other hand, Korean Patent Registration No. 10-0638574 (Registration Date: 2006. 10. 19) discloses a bill counting device having a function of detecting counterfeit bills.

An object of the present invention is to identify a magnetic material that can be detected by distinguishing a plurality of magnetic materials by a method of magnetizing a plurality of magnetic materials with current for magnetization in a magnetic sensing unit for banknotes containing a plurality of magnetic materials having different characteristics. It is to provide a device and a banknote counter having the same.

In addition, another object of the present invention is to first magnetize a plurality of magnetic materials having different characteristics existing in the banknote and then additionally magnetize them with a current for magnetization in the magnetic sensing unit so that the plurality of magnetic materials can be distinguished and detected. It is to provide a magnetic material identification device and a banknote counter having the same.

In addition, another object of the present invention is to magnetize a plurality of magnetic materials having different characteristics existing in banknotes in different magnetic flux directions or to magnetize them alternately so that the degree of coercive force of the magnetic materials can be accurately classified and distributed, thereby making it possible to accurately grasp the distribution of magnetic materials. It is to provide a magnetic material identification device capable of detecting the authenticity of and a banknote counting device equipped with the same.

A magnetic material identification device according to the present invention includes: a magnetic sensing unit that magnetizes a plurality of magnetic materials having different characteristics present in a bill to be transported and distinguishes and detects the plurality of magnetic materials; a magnetization unit capable of magnetizing the plurality of magnetic materials present in the banknote; and a current supplying part for magnetization supplying a current for forming a magnetic field for magnetizing the plurality of magnetic materials in the magnetic sensing part, wherein the current supplying part for magnetization has a magnetic field in a direction opposite to the direction of the magnetic field formed in the magnetizing part. Characterized in that a direct current is applied to form.
In addition, the magnetic material identification device according to the present invention includes a magnetic sensing unit that magnetizes a plurality of magnetic materials having different characteristics present in a bill to be transported and distinguishes and detects the plurality of magnetic materials; and a current supplying part for magnetization supplying a current for forming a magnetic field for magnetizing the plurality of magnetic materials in the magnetic sensing part, wherein the current supplying part for magnetization supplies the magnetic material in the magnetic sensing part in opposite directions. An alternating current of a predetermined frequency is applied to the magnetic sensing unit to alternately magnetize it into a magnetic field, and the magnetization of the plurality of magnetic materials is changed by the direction of the alternately magnetized magnetic field, and the signal is induced and sensed accordingly. It is characterized in that the plurality of magnetic materials are distinguished and sensed by determining the change size of .

In addition, it is characterized in that it is a banknote counter equipped with a magnetic material identification device according to the present invention.

According to the present invention, with respect to banknotes containing a plurality of magnetic materials having different characteristics, a plurality of magnetic materials can be distinguished and detected by a method of magnetizing a plurality of magnetic materials with current for magnetization in a magnetic sensor, thereby detecting the authenticity of a bill. It has the effect of being able to more accurately determine whether or not.

In addition, according to the present invention, by first magnetizing a plurality of magnetic materials having different characteristics existing in the banknote and then further magnetizing them with a current for magnetization in the magnetic sensing unit, the plurality of magnetic materials can be distinguished and sensed. It has the effect of discriminating the authenticity of banknotes more precisely.

In addition, according to the present invention, the classification and distribution of the degree of coercive force of a plurality of magnetic materials can be accurately grasped by a method of magnetizing a plurality of magnetic materials having different characteristics existing in banknotes in different magnetic flux directions or magnetizing alternately. It has the effect of determining the authenticity of the banknote more precisely.

1 is a block diagram showing the configuration of a magnetic material identification device according to an embodiment of the present invention.
2 is a diagram schematically illustrating a magnetic sensing unit according to an embodiment of the present invention.
3 is a diagram showing a hysteresis curve of a magnetic material according to an embodiment of the present invention.
4 is a block diagram showing the configuration of a magnetic material identification device according to another embodiment of the present invention.
5 is a diagram showing an example of a magnetic detection waveform for a hard/soft magnetic material according to another embodiment of the present invention.
6 is a block diagram showing the configuration of a magnetic material identification device according to another embodiment of the present invention.
7 is a graph showing a difference in magnetization with respect to a detection result of a plurality of magnetic materials according to another embodiment of the present invention.
8 is a block diagram showing the configuration of a magnetic material identification device according to another embodiment of the present invention.
9 is a graph showing a difference in magnetization with respect to a detection result of a plurality of magnetic materials according to a modified example of another embodiment of the present invention.

Hereinafter, embodiments of a magnetic material identification device according to the present invention will be described with reference to the accompanying drawings.

In this process, the thickness of lines or the size of components shown in the drawings may be exaggerated for clarity and convenience of description. In addition, terms to be described later are terms defined in consideration of functions in the present invention, which may vary according to the intention or practice of the practitioner. Therefore, definitions of these terms will have to be made based on the content throughout this specification.

1 is a block diagram showing the configuration of a magnetic material identification device according to an embodiment of the present invention, FIG. 2 is a diagram schematically showing a magnetic sensing unit according to an embodiment of the present invention, and FIG. 3 is an embodiment of the present invention. It is a diagram showing a hysteresis curve of a magnetic material according to an example, FIG. 4 is a block diagram showing the configuration of a magnetic material identification device according to another embodiment of the present invention, and FIG. It is a diagram showing an example of a magnetic detection waveform for a magnetic material, FIG. 6 is a block diagram showing the configuration of a magnetic material identification device according to another embodiment of the present invention, and FIG. 7 is a block diagram showing another embodiment of the present invention. 8 is a block diagram showing the configuration of a magnetic material identification device according to another embodiment of the present invention, and FIG. 9 is another embodiment of the present invention. It is a graph showing the difference in magnetization with respect to the detection result of a plurality of magnetic materials according to a modification of another embodiment.

Referring to FIGS. 1 and 2 , a magnetic material identification device 1 according to an embodiment of the present invention includes a magnetic detection unit 10 and a current supply unit 20 for magnetization.

The bills 30 are conveyed in the direction of the arrow A along the conveying path surface 40 by various conveying means (not shown) such as conveying belts or conveying rollers. The banknote 30 includes a magnetic material 31 as an anti-counterfeiting element. The magnetic material 31 is included in the bill 30 when the bill 30 is printed with magnetic ink when the bill 30 is manufactured, and for example, one type of magnetic material, that is, a hard magnetic material having a high coercive force and a coercive force It may be formed of any one of these small soft magnetic materials, and may be formed including a plurality of magnetic materials having different characteristics to enhance anti-counterfeiting, that is, hard magnetic materials and soft magnetic materials classified according to the magnitude of coercive force. . For convenience of description of the present invention, the plurality of magnetic materials 31 are described by taking hard magnetic materials and soft magnetic materials as examples. In this way, when the bill 30 includes a plurality of magnetic materials 31 having different characteristics, the magnetic sensing unit 10 should detect the existence of both hard magnetic materials and soft magnetic materials while distinguishing them. do.

The magnetic sensor 10 magnetizes the plurality of magnetic materials 31 contained in the bills 30 to be transferred and measures a current signal induced therefrom according to the coercive force of the plurality of magnetized magnetic materials 31. By doing so, the plurality of magnetic materials 31 are classified and detected.

The current supply unit 20 for magnetization generates the magnetic field in the magnetic sensing unit 10 to magnetize the plurality of magnetic materials 31 to the magnetic sensing unit 10 with a current (direct current or alternating current) of a predetermined intensity. ) is applied.

Referring to FIG. 2 as an example, the magnetic sensing unit 10 is disposed to face the transfer path surface 40 on one side of which the bill 30 is transferred, and the detection core 12 and the detection coil ( 11), and detects the magnetic force of the plurality of magnetic materials 31 present in the banknote 30 conveyed along the conveyance path surface 40. That is, when the bill 30 passes through the measurement gap 13 of the detection core 12, the detection coil 11 wound around the detection core 12 by the magnetic field induced in the detection core 12 Current is induced according to Faraday's law of electromagnetic induction, and the induced current signal is measured to detect the presence or absence of the plurality of magnetic materials 31.

At this time, the magnetization current supply unit 20 applies a magnetization current (direct current or alternating current) to the detection coil 11 to generate a magnetic field in the detection core 12 so that the bill 30 passes through the detection core 12. ) to magnetize the plurality of magnetic materials 31 present in.

In detail, since magnetization is performed directly in the magnetic sensing unit 10 that detects the plurality of magnetic materials 31, it is possible to detect magnetic materials 31 (eg, soft magnetic materials) having a low coercive force 14. . Conventionally, in the case of a method of magnetizing using a permanent magnet in front of the magnetic sensing unit 10, the magnetic material 31 having a low coercive force almost loses magnetism when it reaches the magnetic sensing unit 10 after being magnetized, so that the magnetic sensing unit (10) was difficult to detect, and when the bill 30 includes both the magnetic material 31 with low coercive force and the magnetic material 31 with high coercive force, it was not expected to detect them separately.

Referring to FIG. 3, according to the hysteresis curve, the intensity (H) of the magnetic field tends to align the atomic magnets (not shown) in the magnetic material 31 to be parallel to the magnetic field. The effect of this alignment process is to increase the magnetic flux density (B) in the magnetic material (31). The alignment process does not occur simultaneously with the change in the external magnetic field, but occurs with a delay. As the magnitude of the external magnetic field increases, the magnetic flux density (B) reaches the saturation magnetism (15), which is the maximum value that appears when all atomic magnets in the magnetic material (31) are aligned in the same direction. When the strength of the magnetic field decreases, the magnetic flux density (B) decreases while being delayed by the change in the strength (H) of the magnetic field. Therefore, even when the strength of the magnetic field (H) becomes zero, the magnetic flux density (B) has a positive value called the coercive force (14). As for the magnetic flux density (B) itself, when the strength (H) of the magnetic field is further increased in the opposite direction, the direction of the magnetic flux density (B) reverses and eventually reaches a saturation value (not shown) in the opposite direction again. At this time, the magnetic material All atomic magnets (not shown) in (31) are perfectly aligned in opposite directions.

Referring to FIGS. 4 and 5, another embodiment of the present invention is described. The magnetic material identification device 1 according to this embodiment includes a DC current supply unit 21 for magnetization and a magnetic detection unit 10 And it may be configured to include a magnetization unit (23).

The bills 30 are conveyed in the direction of the arrow A along the conveying path surface 40 by various conveying means (not shown) such as conveying belts or conveying rollers.

The magnetization part 23 may be composed of a plurality of magnetic materials 31 included in the bill 30, that is, a permanent magnet or an electromagnet having a magnetic force capable of sufficiently magnetizing hard magnetic materials and soft magnetic materials, , A plurality of magnetic materials 31 having different characteristics present in the bill 30 that is disposed at a predetermined position in front of the magnetic sensing unit 10 on the transfer path of the bill 30 and is conveyed along the transfer path surface 40 ) to magnetize. At this time, the plurality of magnetic materials 31 are magnetized in a predetermined magnetic field direction by the magnetizing part 23 .

The magnetic sensing unit 10 detects the plurality of magnetized magnetic materials 31 and identifies whether or not the plurality of magnetic materials 31 are present in a normal position of the bill 30 .

The magnetization DC current supply unit 21 supplies DC current that generates a magnetic field in a direction opposite to the direction of the magnetic field formed by the magnetization unit 23 to the magnetic sensing unit 10 so as to detect the magnetic material 31. It is configured to be magnetized in a direction opposite to the direction of the magnetic field in the magnetization unit 23 . That is, when the magnetization unit 23 is a permanent magnet and the direction is set to be, for example, an S pole, magnetization by applying a magnetization current to the magnetic sensing unit 10 is configured to be detected as, for example, an N pole signal.

Specifically, by magnetizing the plurality of magnetic materials 31 in the magnetic sensing unit 10 in a direction opposite to the direction of the magnetic field in the magnetization unit 23, according to the difference in coercive force 14 of the magnetic material 31 The plurality of magnetic materials 31 may be distinguished and sensed using signal waveforms formed by the plurality of magnetic materials 31 having different characteristics by being magnetized with magnetic fields in opposite directions.

For example, the magnetization unit 23 strongly magnetizes the magnetic material 31 with a magnetic force (eg, 1000 gauss or more) capable of sufficiently magnetizing all of the plurality of magnetic materials 31, that is, soft magnetic materials or hard magnetic materials. magnetization (eg, S pole), and the DC current supply unit 21 for magnetization generates a direct current (eg, 0.5 to 2 mA) that generates an induced magnetic field in the opposite direction (eg, N pole) to the magnetic sensing unit 10 supplied to magnetize the magnetic material 31 in the direction opposite to the direction of the magnetic field in the magnetizing portion 23, much weaker than the magnetic material 31 to a size so that the hard magnetic material does not demagnetize the magnetic material ( 31) to magnetize. At this time, the hard magnetic material has a high coercive force, so even after being magnetized in the magnetization unit 23, it is not demagnetized by the magnetization current of the magnetic sensing unit 10 while maintaining magnetism, and the magnetized unit 23 A signal waveform is formed by magnetism, and the soft magnetic material loses the magnetized polarity in the magnetization unit 23 due to its low coercive force and is demagnetized, resulting in magnetism in the direction of the magnetic field formed by the magnetic sensing unit 10 (ie, the N pole). Since the signal waveform is formed by, a signal of the opposite waveform to that of the hard magnetic material is formed.

Therefore, the magnetic sensing unit 10 distinguishes the hard magnetic material from the soft magnetic material by the waveform formed as described above and can detect it. That is, since the polarity of the waveform formed by the hard magnetic material and the waveform formed by the soft magnetic material are formed oppositely, the hard magnetic material and the soft magnetic material can be distinguished and detected by the shape of the waveform, for example.

In this regard, the intensity of the DC current supplied from the DC current supply unit 21 for magnetization may vary depending on the characteristics of the magnetic sensing unit 10 used and the characteristics of the magnetic material 31 included in the banknote 30. Depending on the type of the bill 30, the magnetic field exceeding the coercive force 14 of the magnetic material having the weakest coercive force 14 among the plurality of magnetic materials 31 included in the bill 30 It is desirable to apply a current of an intensity suitable for the corresponding characteristic within an intensity range in which the coercive force 14 has a magnetic field that does not exceed the coercive force 14 of the strongest material.

Referring to FIG. 5, as shown in (a) of FIG. 5, when the bill 30 passes through the magnetization portion 23 of the magnetic material identification device 1 of FIG. 4, The magnetization unit 23 magnetizes the plurality of magnetic materials 31 in a negative direction. When passing through the magnetization part 23, the hard magnetic material included in the bill 30 is magnetized in the negative direction at the signal detection time point a1, and the signal waveform is output in the form of a falling waveform as shown, When passing through the sensing unit 10, even if the magnetic field direction is reversed, it is magnetized with a weaker magnetic field that does not exceed the coercive force 14, so the magnetic field direction does not change at the signal detection time point a2 and is still magnetized in the negative direction. The signal waveform is similarly output in a form starting with a falling waveform.

Referring to (b) of FIG. 5, when the bill 30 passes through the magnetization part 23 of the magnetic material identification device 1 of FIG. 4, the soft magnetic material included in the bill 30 detects a signal. Similarly at the time point b1, it is magnetized in the negative direction and the signal waveform is output in the form of a falling waveform, and when it passes through the magnetic sensing unit 10, it is magnetized with a magnetic field exceeding the coercive force 14 of the soft magnetic material. It can be seen that the direction of the magnetic field is changed at the signal detection time point (b2) to be magnetized in the positive direction, and the signal waveform is output in the form of changing to a rising waveform and starting.

Referring to (c) of FIG. 5, as explained more simply, this time, in the polarity opposite to that of (a) and (b), the first direction (either hard magnetic material or soft magnetic material) That is, it is magnetized in the positive direction (starting with a rising waveform), and the hard magnetic material with high coercive force maintains its polarity (and direction) until it reaches the magnetic sensing unit 10 and is magnetized in the magnetic sensing unit 10. It is virtually unaffected by the weaker magnetic field in the opposite direction produced by the current, maintaining its original polarity (i.e. starting with a rising waveform). However, the soft magnetic material is magnetized in the first direction (ie, the positive direction) in the magnetization unit 23 (starting with the rising waveform), but since the coercive force is weak, it is demagnetized and loses polarity before reaching the magnetic sensing unit 10. The soft magnetic material that is discarded and demagnetized when passing through the magnetic sensing unit 10 reverses the first direction (i.e., , with opposite polarity by the magnetizing current) (i.e. starting with a falling waveform).

As described above, in the present embodiment, a DC magnetization current is applied to form weak magnetic force in a direction opposite to the magnetic field direction of the strong magnetic force formed in the magnetization unit 23 in the magnetic sensing unit 10. Based on the shape of the detection signal waveform, a plurality of magnetic materials 31 contained in the banknote 30, that is, hard magnetic materials and soft magnetic materials can be distinguished and detected.

Next, Fig. 6 and Fig. 7 show another embodiment of the present invention. The magnetic material identification device 1 according to the present embodiment includes an alternating current supply unit 22 for magnetization and a magnetic detection unit 10 .

The bills 30 are conveyed in the direction of the arrow A along the conveyance path surface 40 by means of conveyance (not shown) such as conveyance belts or conveyance rollers.

The magnetic sensing unit 10 magnetizes a plurality of magnetic materials 31 having different characteristics contained in the bill 30 to be transferred so that the plurality of magnetic materials 31 are present in the normal position of the bill 30. It is configured to identify whether or not

The alternating current supply unit 22 for magnetization alternately magnetizes the magnetic material 31 with magnetic fields in opposite directions to the magnetic sensing unit 10 at a predetermined frequency. apply current

In detail, referring to the graph of FIG. 7, the magnetic sensing unit 10 alternately magnetizes the plurality of magnetic materials 31 in opposite directions to each other, so that the difference in coercive force 14 of the magnetic materials 31, That is, depending on whether the material is a soft magnetic material or a hard magnetic material, the degree of magnetization is changed by the direction of alternating magnetization, and the size of the change in the induced and sensed signal is determined accordingly, so that the plurality of magnetic materials 31 having different magnetic characteristics, such as hard magnetic materials, Magnetic material and soft magnetic material can be distinguished and detected.

More specifically, the hard magnetic material 31 having a high coercive force 14 does not have a large change in magnetization (ie, has a property that is maintained after magnetization) (a3), and a soft magnetic material having a low coercive force 14 Since (31) has a relatively large change in magnetization (that is, it has a property of being demagnetized after magnetization) (b3), different magnetism can be obtained by comparing the magnitude of change in detection signals between each other or by analyzing the frequency characteristics of alternating magnetization. A plurality of magnetic materials 31 having characteristics may be separately detected.

Furthermore, the strength of the alternating current for magnetization of the alternating current supply unit 22 for magnetization should be different depending on the characteristics of the magnetic sensor 10 employed and the characteristics of the magnetic material 31 included in the banknote 30. The range of strength does not allow the coercive force 14 of the magnetic materials 31 included in the bill 30 to reach saturation magnetism 15 beyond the coercive force 14 of the strongest material, depending on the type of bill 30. It is preferable to apply an alternating current of an intensity that does not match.

Next, FIG. 8 and FIG. 9 show another embodiment of the present invention. The magnetic material identification device 1 according to the present embodiment includes an alternating current supply unit 22 for magnetization, a magnetic detection unit 10, and a magnetization unit 23, and as shown in FIG. 6, the magnetization Except for the structure of the part 23, the rest of the structure is the same, so the description will be centered on the magnetization part 23.

The magnetizing portion 23 is configured to form a magnetic field in a predetermined direction and is disposed on the conveyance path of the bill 30, and has a plurality of different characteristics present in the bill 30 conveyed along the conveyance path surface 40. The magnetic material 31 of the magnetizes.

Specifically, the hard magnetic material 31 having a high coercive force 14 among the plurality of magnetic materials 31 is magnetized by the magnetization part 23 and magnetized in a direction according to the magnetic field characteristics of the magnetization part 23. It enters the magnetic sensing unit 10 while maintaining the degree, and the soft magnetic material 31 with low coercive force 14 loses magnetization immediately after passing through the magnetization unit 23, so it is almost demagnetized. passes through the magnetic sensing unit 10. The method of distinguishing and identifying the demagnetized soft magnetic material 31 and the hard magnetic material 31 maintaining the magnetized state by the magnetic sensing unit 10 and the magnetization alternating current supply unit 22 has been described above. omit the explanation.

Furthermore, the magnetic flux density (B) of the magnetizing part (23) has a magnetic flux density (B) of a size that reaches the saturation magnetism (15) regardless of the type of magnetic material (31) present in the banknote (30). It is desirable to have

On the other hand, the magnetic material identification device 1 of the above-described embodiments is suitable for various banknote processing devices that should have a magnetic sensor (not shown) to detect counterfeit money such as a banknote counting machine or a banknote sorting machine according to the implementation environment or the intention of the practitioner. At least those skilled in the art will be able to fully understand that any number can be employed. Therefore, with respect to the banknote 30 including a plurality of magnetic materials 31 (eg, hard magnetic material and soft magnetic material) having different characteristics as a more improved anti-counterfeiting banknote element, the plurality of magnetic materials 31 (eg, : Soft magnetic material and hard magnetic material) can be distinguished and detected, so counterfeit discrimination performance can be further improved.

The present invention has been described with reference to the embodiments shown in the drawings, but this is only exemplary, and those skilled in the art can make various modifications and equivalent other embodiments. will understand

Therefore, the true technical protection scope of the present invention should be determined by the claims.

1: magnetic material identification device 10: magnetic detection unit
11: detection coil 12: detection core
13: detection gap 14: coercive force
15: saturation magnet 20: current supply for magnetization
21: DC current supply for magnetization 22: AC current supply for magnetization
23: magnetization part 30: bill
31: magnetic material 40: transfer path surface
A: bill transfer direction B: magnetic flux density
H: strength of magnetic field a1,a2,b1,b2: magnetic detection signal
a3: magnetization of hard magnetic materials b3: magnetization of soft magnetic materials

Claims (8)

In the magnetic material identification device,
a magnetic sensing unit that magnetizes a plurality of magnetic materials having different characteristics existing in the transferred banknotes and separately detects the plurality of magnetic materials;
a magnetization unit capable of magnetizing the plurality of magnetic materials present in the banknote; and
The magnetization sensing unit includes a magnetization current supply unit for supplying a current forming a magnetic field for magnetizing the plurality of magnetic materials,
The magnetization current supply unit applies a DC current to form a magnetic field in a direction opposite to a direction of a magnetic field formed by the magnetization unit.
According to claim 1,
The plurality of magnetic materials include a hard magnetic material and a soft magnetic material, and the magnetization unit is disposed in front of the magnetic sensing unit on the transfer path of the banknote.
According to claim 1,
The magnetic material identification device of claim 1 , wherein the current supply unit for magnetization applies a DC magnetization current to form a magnetic field having a weaker magnetic force than the magnetic field formed by the magnetization sensing unit in the magnetization unit.
delete delete According to claim 1,
The magnetic material identification device according to claim 1 , wherein the magnetic sensing unit classifies and detects the plurality of magnetic materials based on a signal waveform formed by a magnetic field formed by itself and a magnetic field formed by the magnetization unit.
In the magnetic material identification device,
a magnetic sensing unit that magnetizes a plurality of magnetic materials having different characteristics existing in the transferred banknotes and separately detects the plurality of magnetic materials; and
The magnetization sensing unit includes a magnetization current supply unit for supplying a current forming a magnetic field for magnetizing the plurality of magnetic materials,
The magnetization current supply unit applies an alternating current of a predetermined frequency to the magnetic sensing unit to alternately magnetize the magnetic material in the magnetic sensing unit with magnetic fields in opposite directions;
Magnetic material characterized in that the magnetization of the plurality of magnetic materials is changed by the direction of the magnetic field alternately magnetized, and the magnitude of change in the signal that is inductively sensed is determined accordingly to distinguish and sense the plurality of magnetic materials. identification device.
A banknote counting machine comprising the magnetic substance identification device according to any one of claims 1 to 3 or 6 or 7.

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